JP4585686B2 - Chemical fertilizer with organic matter and method for producing the same - Google Patents
Chemical fertilizer with organic matter and method for producing the same Download PDFInfo
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Description
【0001】
【発明の属する技術分野】
本発明は、ジシアンジアミドと有機物とを含有する有機物入り化成肥料及びその製造方法に関する。
【0002】
【従来の技術】
ここ数年“環境保全型農業”という言葉がはやりであり、いままでの多肥集約型農業から低投入・持続型農業への変換が叫ばれている。
こうした背景の中で化学肥料、特に一般化成肥料はその肥効が速効性である反面、すぐに硝酸化、溶脱して地下水中の硝酸態窒素含量を高めたり、オゾン層破壊物質の一つとなっている亜酸化窒素を生成することから環境汚染物質の元凶の如くいわれている。
【0003】
そこで化学合成緩効性窒素入り肥料や硝酸化成抑制剤入り肥料が開発されてきているが、それらは高価な硝酸化成抑制剤等を肥料中に多量に入れる必要があるためどうしても高価格にならざるを得ず、また効果も満足できるものではなかった。また、優れた硝酸化抑制剤としてジシアンジアミドが知られており、ジシアンジアミドを添加した肥料が用いられているが、それらのジシアンジアミド入り肥料はその製造過程でジシアンジアミドが変成してしまったり、あるいは得られた肥料のジシアンジアミドの緩効性・硝酸化抑制能が十分でない等の問題があった。
【0004】
一方、被覆肥料がその救世主として名乗りをあげており、たしかに作物の吸収に見合った成分を溶出できるという大きなメリットがある反面、その被覆材料は土壌中で分解されない合成高分子化合物が大部分であり、むしろ環境汚染物質になる可能性がある。
また、有機肥料も安全性や健康の面から大きくクローズアップされており、有機農業がもてはやされているが、これもまた肥効がはっきりしないこと、高価格等の面で問題点を残している。
【0005】
【発明が解決しようとする課題】
本発明は、上記問題点を解決し、緩効性を高め、硝化抑制能を強化し、さらに有機物を増強した環境保全型肥料を提供することを目的とする。
【0006】
【課題を解決するための手段】
本発明は、環境負荷軽減の施肥技術という観点から、▲1▼作物の吸収量に見合った養分を持続的に供給する肥料。▲2▼土壌中に過剰養分を蓄積させない肥料。▲3▼シグモイド型の窒素溶出をする肥料を開発することを念頭に置き、種々検討を加えた。本発明者らは、ベース肥料としてシグモイド型の微生物分解性を有する石灰窒素変成物を用い、中でもジシアンジアミドに焦点を合せ、これと有機物とを共存させて他の肥料原料とともに造粒した化成肥料とすることにより、製造過程でのジシアンジアミドの変成を防ぎ、かつ施肥した場合の硝酸化成抑制能の持続性を高めることができることを見出し、本発明を完成させるに至った。
【0007】
即ち、本発明は以下の発明を包含する。
(1)ジシアンジアミド及び有機物を含む肥料原料を造粒して得られる有機物入り化成肥料。
(2)ジシアンジアミド及び有機物を含む肥料原料を造粒することを特徴とする有機物入り化成肥料の製造方法。
【0008】
【発明の実施の形態】
ジシアンジアミドは緩効性窒素源となるだけではなく硝酸化成抑制能の両方を兼ね備える物質としてその存在は広く知られている。肥料における硝酸化成抑制能を強化することにより、その肥料由来の窒素だけでなく土壌由来窒素の硝酸化成化も抑え、無機化された窒素の流亡、脱窒を抑制し、窒素の利用率を高める効果が期待される。
【0009】
しかしながら、ジシアンジアミドは酸性条件で温度を加えると定量的にグアニル尿素に変成し、さらに厳しい条件下ではグアニジンやメラミン等に変成する。このため通常の造粒条件下ではジシアンジアミドの変成が避けられない。ジシアンジアミドは高度化成のように中性付近では変成に対しての抵抗性は強いといえるが、しかしながら温度のかかる乾燥過程での変成はやはり避け難い。また、酸性領域の多い低度化成では一般的にほとんどジシアンジアミド態としては残らない。
【0010】
しかしながら、本発明者らはジシアンジアミド及び有機物を含む肥料原料を用いると、ジシアンジアミドが変成しやすい通常の肥料製造条件下でも、ジシアンジアミドが低度化成で元の量の約70〜90%、高度化成では大部分が残存することを見出した。これは親油性のジシアンジアミドが有機物に包まれ、酸を触媒とする加水分解反応を受けにくくなっているためであると推定される。
【0011】
また、本発明者らはジシアンジアミド由来の硝酸化成抑制能が有機物との併用により持続性が強化されること、さらに、有機物の穏やかな無機化後の急激な硝酸化成化を抑制できることを見出した。これもジシアンジアミドと有機物との相互作用によるためであると推定される。
【0012】
以下に、本発明の有機物入り化成肥料について説明する。
本発明で用いられる肥料原料は、ジシアンジアミド及び有機物を含むものであり、さらに通常使用される肥料成分を混合してもよい。
ジシアンジアミドの添加量は、多く入れすぎると作物に対する障害が懸念されることから重要であり、通常、ジシアンジアミドの窒素分が本発明の化成肥料中の全窒素に対し、重量で0.01〜25%、好ましくは1〜20%の範囲内で可能である。
【0013】
本発明で用いる有機物とは動植物に由来するものであり、「改訂四版 肥料用語事典」肥料用語事典編集委員会編、肥料協会新聞部発行、第267頁に記載のものをいう。そのような有機物としては、例えば魚粕、蒸製骨粉、乾血粉、菜種油粕、大豆油粕等の動植物有機質肥料を始め、発酵乾ぷん肥料、汚泥肥料、乾燥菌体肥料等の有機性廃棄物肥料や牛糞堆肥、豚糞堆肥、バーク堆肥等の堆肥類が挙げられ、これらの中から1種以上を選んで使用することができる。
【0014】
有機物の使用割合とジシアンジアミドの変成率との間には負の相関があり、有機物の使用量を増やすほど変成率は下がり、ジシアンジアミドの残存率が高まる。前記有機物の一般的な使用量としては、本発明の化成肥料重量に対して5%〜80%、好ましくは10%〜70%である。5%未満では、大部分のジシアンジアミドが変成してしまい、80%を超えると今度は造粒率が低下してしまう傾向にある。
本発明で用いられる肥料原料としては、ジシアンジアミド及び有機物の他に通常用いられる肥料成分を適宜混合して用いることができる。そのような肥料成分として、例えば以下のようなものが挙げられる。
【0015】
窒素源として、硫安、塩安、硝安を始めとする肥料取締法に基づく窒素質肥料が使用できる。なお、IB窒素(イソブチルアルデヒド縮合尿素肥料)、CDU窒素(アセトアルデヒド縮合尿素肥料)、ホルム窒素(ホルムアルデヒド加工尿素肥料)、オキサミド、石灰窒素、グアニル尿素等の緩効性窒素との併用は緩効性を高めるため望ましい。燐酸源としては、過リン酸石灰、重過リン酸石灰、熔成リン肥を始めとする肥料取締法に基づくリン酸質肥料を使用できる。カリ源としては、硫酸加里、塩化加里を始めとする肥料取締法に基づくカリ質肥料を使用することができる。その他、石灰質肥料、けい酸質肥料、苦土肥料、マンガン質肥料、ほう素質肥料、微量要素複合肥料等を自由に選択して使用することができる。また、二成分複合化成肥料の代表であるリン安の使用も可能である。さらに、ピートモス、腐植酸質資材、ベントナイト、ゼオライト、フライアッシュ、石膏等の土壌改良資材との併用も自由に選択できる。これらの肥料成分の使用割合は目的とする成分含量により適宜変動させて使用可能である。
【0016】
本発明の化成肥料は、上記肥料原料を通常の造粒方法により造粒・乾燥して得ることができ、例えば以下のようにして製造できる。
ジシアンジアミド及び有機物を含む肥料原料をパン造粒器やドラム型造粒機等の造粒器に入れ、ジシアンジアミド及び有機物がともに存在する状態で、水を適当に供給しながら十分に混合して造粒する。得られた造粒物を乾燥機(通常90〜120℃、好ましくは100〜110℃)又は天日で乾燥して本発明の化成肥料を得る。
【0017】
このようにして得られる有機物入り化成肥料は、窒素成分を5〜15%、燐酸成分を5〜20%、カリ成分を5〜15%含むことが好ましく、また、そのpHは通常5〜8であり、好ましくは5.5〜7.5である。
本発明の製造方法により得られる化成肥料は、その製造過程中でのジシアンジアミドの変成が少なく、ジシアンジアミドの残存率は、低度化成肥料の場合は通常70%以上、高度化成肥料の場合は通常90%以上とすることができる。なお、残存率とは原料として用いたジシアンジアミドに対する、製造後の肥料中に残存しているジシアンジアミドの割合である。
【0018】
上記のようにジシアンジアミドと有機物とを共存させた肥料原料を用いて造粒することにより、造粒時及び乾燥工程でのジシアンジアミドの変成を防ぐことができ、また硝酸化抑制能の持続性がより高い肥料が得られる。
以下、実施例及び比較例をあげて本発明をさらに詳述するが、本発明はこれら実施例に限定されるものではない。
【0019】
【実施例】
実施例−1
成分8−8−8の肥料(低度化成)の製造
硫安0.78kg、DAP 0.56kg、石膏 1.06kg、塩加 0.54kg、ジシアンジアミド 0.04kgそして発酵乾ぷん肥料(全窒素 3%、全リン酸 5%)1.6kgをパン造粒器に入れて充分混合し、水を適当に供給しながら造粒した。得られた造粒物を105℃の棚段式の乾燥機に4時間入れた後、室温まで冷却し、液体クロマトグラフィー(*1)により肥料中のジシアンジアミドを分析した。
【0020】
その結果、肥料中のジシアンジアミド含量は0.0288kgであり、残存率(*2)は72%だった。
*1:液体クロマトグラフィー測定条件
カラム:Hitachi #3011-C 2.6Φ×250mm
カラム温度: 30℃
溶出液: 0.0125M KH2PO4+ 0.003% H3PO4
*2:残存率=(回収ジシアンジアミド/導入ジシアンジアミド)×100
【0021】
比較例−1
成分8−8−8の肥料の製造
硫安0.86kg、DAP 0.74kg、石膏 1.88kg、塩加 0.54kg、ジシアンジアミド 0.04kgをパン造粒器に入れて充分混合し、水を適当に供給しながら造粒した。得られた造粒物を105℃の棚段式の乾燥機に4時間入れた後、室温まで冷却し、液体クロマトグラフィーにより肥料中のジシアンジアミドを分析した。
その結果、肥料中のジシアンジアミド含量は0.0045kgであり、残存率は11.3%だった。
実施例−1と比較例−1の結果より有機物を入れた方が明らかにジシアンジアミドの残存率が高まることがわかる。
【0022】
実施例−2
成分12−12−12の肥料(高度化成)の製造
石灰窒素変成物(*3)0.20kg、DAP 0.68kg、尿素 0.18kg、硫安 0.70kg、ジシアンジアミド 0.16kg、塩加 0.81kg、過リン酸石灰 0.99kg、石膏 0.12kgそして菌体肥料(全窒素 5%、全リン酸 3%)0.60kgをパン造粒器に入れて充分混合し、水を適当に供給しながら造粒した。得られた造粒物を105℃の棚段式の乾燥機に4時間入れた後、室温まで冷却し、液体クロマトグラフィーにより肥料中のジシアンジアミドを分析した。
その結果、肥料中のジシアンジアミド含量は0.136kgであり、残存率は85%だった。
*3:石灰窒素を硫酸で分解したもの(全窒素 7.7%)
【0023】
実施例−3
成分12−12−12の肥料の製造
石灰窒素変成物0.15kg、DAP 0.59kg、尿素 0.14kg、硫安 0.40kg、ジシアンジアミド 0.12kg、塩加 0.62kg、過リン酸石灰 0.55kg、石膏 0.99kg及び大豆油粕0.45kgをパン造粒器に入れて充分混合し、水を適当に供給しながら造粒した。得られた造粒物を105℃の棚段式の乾燥機に4時間入れた後、室温まで冷却し、液体クロマトグラフィーにより肥料中のジシアンジアミドを分析した。
その結果、肥料中のジシアンジアミド含量は0.101kgであり、残存率は84%だった。
【0024】
比較例−2
成分12−12−12の肥料の製造
石灰窒素変成物0.20kg、DAP 0.42kg、尿素 0.18kg、硫安 0.67kg、ジシアンジアミド 0.16kg、塩加 0.81kg、過リン酸石灰 1.78kg及び石膏 0.12kgをパン造粒器に入れて充分混合し、水を適当に供給しながら造粒した。得られた造粒物を105℃の棚段式の乾燥機に4時間入れた後、室温まで冷却し、液体クロマトグラフィーにより肥料中のジシアンジアミドを分析した。
その結果、肥料中のジシアンジアミド含量は0.089kgであり、残存率は55.6%だった。
【0025】
比較例−3
成分12−12−12の肥料の製造
石灰窒素変成物0.20kg、DAP 0.42kg、尿素 0.18kg、硫安 0.67kg、ジシアンジアミド 0.16kg、塩加 0.81kg、過リン酸石灰 1.78kg及び石膏 0.12kgをパン造粒器に入れて充分混合し、水を適当に供給しながら造粒した。得られた造粒物を天日乾燥した後、液体クロマトグラフィーにより肥料中のジシアンジアミドを分析した。
その結果、肥料中のジシアンジアミド含量は0.131kgであり、残存率は82%だった。
実施例−2及び3と比較例−2及び3の結果より、低度化成ほど大きな差はないが高度化成の場合においても有機物を入れた方がジシアンジアミドの残存率が高まることが示された。
【0026】
実施例−4
成分6−6−5の肥料の製造
石灰窒素変成物0.23kg、MAP 0.39kg、副産窒素肥料(*4) 0.99kg、発酵乾ぷん肥料 1.98kg、菜種油粕 0.45kg、菌体肥料 0.11kg、皮粉 0.45kg、ジシアンジアミド 0.045kg、塩化加里 0.40kg及び石膏0.14kgをパン造粒器に入れて充分混合し、水を適当に供給しながら造粒した。得られた造粒物を105℃の棚段式の乾燥機に4時間入れた後、室温まで冷却し、液体クロマトグラフィーにより肥料中のジシアンジアミドを分析した。
その結果、肥料中のジシアンジアミド含量は0.041kgであり、残存率は91%だった。
*4:酸性硫安液と炭酸カルシウムを反応させた副産窒素肥料(アンモニウム態窒素 8%)
【0027】
実施例−5
成分6−7−7の肥料の製造
石灰窒素変成物0.25kg、MAP 0.18kg、副産窒素肥料1.84kg、ジシアンジアミド0.03kg、塩加0.61kg、過リン酸石灰1.02kg、魚粕1.5kgをパン造粒器に入れて充分混合し、水を適当に供給しながら造粒した。得られた造粒物を105℃の棚段式の乾燥機に4時間入れた後、室温まで冷却し、液体クロマトグラフィーにより肥料中のジシアンジアミドを分析した。
その結果、肥料中のジシアンジアミド含量は0.027kgであり、残存率は90%だった。
【0028】
比較例−4
成分6−7−7の肥料の製造
石灰窒素変成物0.25kg、MAP 0.29kg、副産窒素肥料3.02kg、ジシアンジアミド 0.03kg、塩加 0.61kg及び過リン酸石灰1.23kgをパン造粒器に入れて充分混合し、水を適当に供給しながら造粒した。得られた造粒物を105℃の棚段式の乾燥機に4時間入れた後、室温まで冷却し、液体クロマトグラフィーにより肥料中のジシアンジアミドを分析した。
その結果、肥料中のジシアンジアミド含量は0.005kgであり、残存率は16.7%だった。
【0029】
[硝化抑制効果試験−1]
実施例−2及び比較例−3で調製した肥料を用いて畑条件(土壌:いわき市内畑土、窒素添加量:25mg/50g土壌 水分条件:最大容水量の60%、温度:25℃)で実施した。その結果を以下に示す。
【0030】
【表1】
【0031】
表1の結果より有機物入り肥料の方が硝酸化成抑制にプラスに作用しており、有機物とジシアンジアミドの併用により硝化抑制効果を高める効果が示された。
【0032】
[硝化抑制効果試験−2]
実施例−2及び菜種油粕を用いて畑条件(土壌:結城市内畑土、窒素添加量:20mg/50g土壌 水分条件:最大容水量の60%、温度:25℃)で実施した。その結果を以下に示す。
【0033】
【表2】
【0034】
表2の結果より、菜種油粕単独では急激な硝酸化成化が進行するが、本発明の化成肥料との併用ではそれが抑えられることが示された。
【0035】
[肥効試験]
a/5000ワグネルポットを使用し、実施例−2で調製した肥料と対照として普通高度化成肥料(成分14−14−14)を窒素成分で0.4g/ポットに合せ、水稲(コシヒカリ)を栽培した。施肥:5/10 移植:5/13 収穫:10/1(1999年)
その結果、ポット当りの収量は、対照化成肥料では29.4gであったのに対し、本発明の肥料では33.9gであり、対照化成の場合に比較して115%と高水準の収量が得られた。
【0036】
【発明の効果】
本発明の化成肥料は、緩効性を高め、硝酸化成抑制能を強化し、さらに有機物を増強した肥料であり、施肥の省力化、収量・品質面の向上、さらに環境保全面で有用なものであり、これからの肥料としてその普及が期待されるものである。また、本発明によれば肥料製造過程中でのジシアンジアミドの変成を防ぐことのできる化成肥料の製造方法を提供できる。さらに、本発明の肥料は作物の生育環境を好ましい養分状態に維持することができ、収量及び品質を高めることが可能な肥料である。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an organic-containing chemical fertilizer containing dicyandiamide and an organic substance, and a method for producing the same.
[0002]
[Prior art]
The term “environmental conservation agriculture” has been used for several years, and there has been a call for conversion from conventional fertilizer-intensive agriculture to low-input / sustainable agriculture.
Against this background, chemical fertilizers, especially general fertilizers, are fast-acting, but they are immediately nitrated and leached to increase the nitrate nitrogen content in groundwater and become one of the ozone-depleting substances. It is said to be the source of environmental pollutants because it produces nitrous oxide.
[0003]
So although chemical synthesis slow-release nitrogen-containing fertilizer and nitric acid chemical inhibitor-containing fertilizer have been developed, they are forced to become an expensive nitrification inhibitor such as in really high price because there is a need to put in a large amount in the fertilizer And the effect was not satisfactory. In addition, dicyandiamide is known as an excellent nitrification inhibitor, and fertilizers with dicyandiamide added are used, but these dicyandiamide-containing fertilizers were converted to dicyandiamide or obtained during the production process. There were problems such as the slow release and the ability to suppress nitrification of dicyandiamide as a fertilizer.
[0004]
On the other hand, coated fertilizer has been known as a savior and has the great advantage of being able to elute components suitable for the absorption of crops, but the coated material is mostly synthetic polymer compounds that are not decomposed in the soil. Rather, it can be an environmental pollutant.
In addition, organic fertilizers are greatly highlighted from the viewpoints of safety and health, and organic farming has been nurtured, but this also leaves problems in terms of unclear fertilization and high prices. .
[0005]
[Problems to be solved by the invention]
An object of the present invention is to solve the above-mentioned problems, to provide an environment-conserving fertilizer that enhances slow release, enhances nitrification inhibition ability, and further enhances organic matter.
[0006]
[Means for Solving the Problems]
The present invention is (1) a fertilizer that continuously supplies nutrients commensurate with the absorbed amount of crops from the viewpoint of fertilization technology for reducing environmental impact. (2) Fertilizer that does not accumulate excess nutrients in the soil. (3) Various studies were made with the development of a sigmoid nitrogen-eluting fertilizer in mind. The present inventors use a sigmoid-type lime-nitrogen modified product having microbial degradation as a base fertilizer, focusing on dicyandiamide, among them, a chemical fertilizer granulated together with other fertilizer raw materials in the presence of this and organic matter As a result, it was found that dycyandiamide can be prevented from being transformed during the production process, and the sustainability of the ability to suppress nitrification when fertilized can be increased, and the present invention has been completed.
[0007]
That is, the present invention includes the following inventions.
(1) A chemical fertilizer containing organic matter obtained by granulating a fertilizer raw material containing dicyandiamide and organic matter.
(2) A method for producing an organic-containing chemical fertilizer, comprising granulating a fertilizer raw material containing dicyandiamide and an organic substance.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Dicyandiamide is widely known as a substance that not only serves as a slow-release nitrogen source but also has both nitrification inhibition ability. By enhancing the ability of fertilizers to suppress nitrification, not only fertilizer-derived nitrogen but also soil-derived nitrogen nitrification is suppressed, and the loss and denitrification of inorganic nitrogen are suppressed, increasing the utilization rate of nitrogen. Expected to be effective.
[0009]
However, dicyandiamide quantitatively transforms into guanylurea when temperature is applied under acidic conditions, and transforms into guanidine, melamine, etc. under more severe conditions. For this reason, modification of dicyandiamide is inevitable under normal granulation conditions. Dicyandiamide is highly resistant to metamorphosis near neutrality, as in advanced chemical conversion, but it is still difficult to avoid denaturation during a drying process that requires temperature. Further, in a low-grade chemical with many acidic regions, generally, almost no dicyandiamide state remains.
[0010]
However, when the present inventors use fertilizer raw materials containing dicyandiamide and organic matter, even under normal fertilizer production conditions in which dicyandiamide is likely to be modified, dicyandiamide is low-grade and about 70-90% of the original amount, We found that most remained. This is presumed to be because lipophilic dicyandiamide is encased in an organic substance, making it difficult to undergo an acid-catalyzed hydrolysis reaction.
[0011]
In addition, the present inventors have found that the ability to suppress nitrification derived from dicyandiamide is enhanced by the combined use with an organic substance, and that rapid nitrification after mild mineralization of the organic substance can be suppressed. This is also presumed to be due to the interaction between dicyandiamide and organic matter.
[0012]
Below, the organic-containing chemical fertilizer of this invention is demonstrated.
The fertilizer raw material used in the present invention contains dicyandiamide and an organic substance, and a commonly used fertilizer component may be further mixed.
The amount of dicyandiamide added is important because there is a concern about crop damage if it is added too much. Usually, the nitrogen content of dicyandiamide is 0.01 to 25% by weight with respect to the total nitrogen in the chemical fertilizer of the present invention. , Preferably in the range of 1-20%.
[0013]
The organic matter used in the present invention is derived from animals and plants, and refers to those described in “Revised Fourth Edition Fertilizer Terminology” edited by the Fertilizer Terminology Editorial Committee, published by the Fertilizer Association Newspaper Department, page 267. Examples of such organic substances include animal and plant organic fertilizers such as fish carp, steamed bone meal, dry blood meal, rapeseed oil meal, and soybean oil meal, fermented dry fertilizer, sludge fertilizer, and organic waste fertilizer such as dry cell fertilizer. Composts such as cow manure compost, pig manure compost, and bark compost can be used, and one or more of them can be selected and used.
[0014]
There is a negative correlation between the usage rate of the organic substance and the conversion rate of dicyandiamide, and the conversion rate decreases and the residual rate of dicyandiamide increases as the use amount of the organic substance increases. As a general usage-amount of the said organic substance, it is 5 to 80% with respect to the chemical fertilizer weight of this invention, Preferably it is 10 to 70%. If it is less than 5%, most of the dicyandiamide is denatured, and if it exceeds 80%, the granulation rate tends to decrease.
As a fertilizer raw material used by this invention, the fertilizer component normally used besides dicyandiamide and an organic substance can be mixed suitably, and can be used. Examples of such fertilizer components include the following.
[0015]
Nitrogenous fertilizers based on fertilizer control methods such as ammonium sulfate, ammonium chloride, and ammonium nitrate can be used as the nitrogen source. IB nitrogen (isobutyraldehyde condensed urea fertilizer), CDU nitrogen (acetaldehyde condensed urea fertilizer), form nitrogen (formaldehyde processed urea fertilizer), combined use with slow-release nitrogen such as oxamide, lime nitrogen, guanyl urea, etc. It is desirable to increase. As the phosphate source, phosphate fertilizers based on fertilizer control methods such as superphosphate lime, heavy superphosphate lime, and molten phosphorus fertilizer can be used. As the potash source, potash fertilizers based on the fertilizer control law, such as potassium sulfate and potassium chloride, can be used. In addition, calcareous fertilizers, siliceous fertilizers, clay soil fertilizers, manganese fertilizers, boron fertilizers, trace element compound fertilizers, etc. can be freely selected and used. Moreover, it is also possible to use phosphorus, which is a representative of two-component compound fertilizer. Furthermore, combined use with soil improvement materials such as peat moss, humic acid materials, bentonite, zeolite, fly ash, and gypsum can be freely selected. The use ratio of these fertilizer components can be appropriately varied depending on the intended component content.
[0016]
The chemical fertilizer of this invention can be obtained by granulating and drying the said fertilizer raw material with a normal granulation method, for example, can be manufactured as follows.
The fertilizer raw material containing dicyandiamide and organic matter is put into a granulator such as a bread granulator or drum type granulator, and in the state where both dicyandiamide and organic matter are present, it is mixed thoroughly and granulated while supplying water appropriately. To do. The obtained granulated material is dried with a dryer (usually 90 to 120 ° C., preferably 100 to 110 ° C.) or the sun to obtain the chemical fertilizer of the present invention.
[0017]
The organic fertilizer thus obtained contains 5 to 15% nitrogen component, 5 to 20% phosphoric acid component, and 5 to 15% potassium component, and the pH is usually 5 to 8. Yes, preferably 5.5-7.5.
The chemical fertilizer obtained by the production method of the present invention has little modification of dicyandiamide during the production process, and the residual rate of dicyandiamide is usually 70% or more in the case of low-grade chemical fertilizer and usually 90 in the case of advanced chemical fertilizer. % Or more. The residual rate is the ratio of dicyandiamide remaining in the fertilizer after production to dicyandiamide used as a raw material.
[0018]
By granulating using a fertilizer raw material in which dicyandiamide and an organic substance coexist as described above, it is possible to prevent dicyandiamide from being transformed during granulation and in the drying process, and to further maintain the ability to suppress nitrification. High fertilizer is obtained.
EXAMPLES Hereinafter, although an Example and a comparative example are given and this invention is further explained in full detail, this invention is not limited to these Examples.
[0019]
【Example】
Example-1
Manufacture of component 8-8-8 fertilizer (low-grade chemical) 0.78 kg ammonium sulfate, 0.56 kg DAP, 1.06 kg gypsum, 0.54 kg salt, 0.04 kg dicyandiamide and fermented dry fertilizer (total nitrogen 3% , 1.6 kg of total phosphoric acid) was placed in a bread granulator and mixed well, and granulated while supplying water appropriately. The obtained granulated material was placed in a shelf dryer at 105 ° C. for 4 hours, cooled to room temperature, and analyzed for dicyandiamide in the fertilizer by liquid chromatography (* 1).
[0020]
As a result, the dicyandiamide content in the fertilizer was 0.0288 kg, and the residual rate (* 2) was 72%.
* 1: Liquid chromatography measurement condition column: Hitachi # 3011-C 2.6Φ × 250mm
Column temperature: 30 ° C
Eluent: 0.0125M KH 2 PO 4 + 0.003% H 3 PO 4
* 2: Residual rate = (recovered dicyandiamide / introduced dicyandiamide) × 100
[0021]
Comparative Example-1
Manufacture of component 8-8-8 fertilizer 0.86 kg of ammonium sulfate, 0.74 kg of DAP, 1.88 kg of gypsum, 0.54 kg of salt, 0.04 kg of dicyandiamide are mixed well in a bread granulator, and water is properly mixed Granulated while feeding. The obtained granulated material was placed in a shelf dryer at 105 ° C. for 4 hours, cooled to room temperature, and analyzed for dicyandiamide in the fertilizer by liquid chromatography.
As a result, the dicyandiamide content in the fertilizer was 0.0045 kg, and the residual rate was 11.3%.
It can be seen from the results of Example-1 and Comparative Example-1 that the residual rate of dicyandiamide is clearly increased when an organic substance is added.
[0022]
Example-2
Manufacture of fertilizer (advanced chemical conversion) of component 12-12-12 0.20 kg of lime nitrogen modified product (* 3), DAP 0.68 kg, urea 0.18 kg, ammonium sulfate 0.70 kg, dicyandiamide 0.16 kg, salt added 0. 81kg, lime superphosphate 0.99kg, gypsum 0.12kg and cell fertilizer (total nitrogen 5%, total phosphoric acid 3%) 0.60kg put in a bread granulator and mix well, supplying water appropriately While granulating. The obtained granulated material was placed in a shelf dryer at 105 ° C. for 4 hours, cooled to room temperature, and analyzed for dicyandiamide in the fertilizer by liquid chromatography.
As a result, the dicyandiamide content in the fertilizer was 0.136 kg, and the residual rate was 85%.
* 3: Lime nitrogen decomposed with sulfuric acid (total nitrogen 7.7%)
[0023]
Example-3
Manufacture of fertilizer for component 12-12-12 0.15 kg of lime nitrogen modification, 0.59 kg of DAP, 0.14 kg of urea, 0.40 kg of ammonium sulfate, 0.12 kg of dicyandiamide, 0.62 kg of salt, lime superphosphate 0. 55 kg, 0.99 kg of gypsum and 0.45 kg of soybean oil cake were put in a bread granulator and mixed well, and granulated while supplying water appropriately. The obtained granulated material was placed in a shelf dryer at 105 ° C. for 4 hours, cooled to room temperature, and analyzed for dicyandiamide in the fertilizer by liquid chromatography.
As a result, the dicyandiamide content in the fertilizer was 0.101 kg, and the residual rate was 84%.
[0024]
Comparative Example-2
Manufacture of fertilizer of component 12-12-12 0.20 kg of lime nitrogen modified product, 0.42 kg of DAP, 0.18 kg of urea, 0.67 kg of ammonium sulfate, 0.16 kg of dicyandiamide, 0.81 kg of salt, lime superphosphate 78 kg and 0.12 kg of gypsum were put in a bread granulator, mixed well, and granulated while supplying water appropriately. The obtained granulated material was placed in a shelf dryer at 105 ° C. for 4 hours, cooled to room temperature, and analyzed for dicyandiamide in the fertilizer by liquid chromatography.
As a result, the dicyandiamide content in the fertilizer was 0.089 kg, and the residual rate was 55.6%.
[0025]
Comparative Example-3
Manufacture of fertilizer of component 12-12-12 0.20 kg of lime nitrogen modified product, 0.42 kg of DAP, 0.18 kg of urea, 0.67 kg of ammonium sulfate, 0.16 kg of dicyandiamide, 0.81 kg of salt, lime superphosphate 78 kg and 0.12 kg of gypsum were put in a bread granulator, mixed well, and granulated while supplying water appropriately. The obtained granulated product was dried in the sun, and then dicyandiamide in the fertilizer was analyzed by liquid chromatography.
As a result, the dicyandiamide content in the fertilizer was 0.131 kg, and the residual rate was 82%.
From the results of Examples-2 and 3 and Comparative Examples-2 and 3, it was shown that the residual rate of dicyandiamide is increased by adding an organic substance even in the case of advanced chemical conversion although there is no great difference as low chemical conversion.
[0026]
Example-4
Manufacture of component 6-6-5 fertilizer 0.23 kg of lime nitrogen modification, MAP 0.39 kg, by-product nitrogen fertilizer (* 4) 0.99 kg, fermented dry fertilizer 1.98 kg, rapeseed oil cake 0.45 kg, fungus 0.11 kg of body fertilizer, 0.45 kg of skin powder, 0.045 kg of dicyandiamide, 0.40 kg of potassium chloride and 0.14 kg of gypsum were mixed in a bread granulator and granulated while supplying water appropriately. The obtained granulated material was placed in a shelf dryer at 105 ° C. for 4 hours, cooled to room temperature, and analyzed for dicyandiamide in the fertilizer by liquid chromatography.
As a result, the dicyandiamide content in the fertilizer was 0.041 kg, and the residual rate was 91%.
* 4: By-product nitrogen fertilizer made by reacting acidic ammonium sulfate solution and calcium carbonate (8% ammonium nitrogen)
[0027]
Example-5
Manufacture of fertilizer of component 6-7-7 0.25 kg of lime nitrogen modification, MAP 0.18 kg, byproduct nitrogen fertilizer 1.84 kg, dicyandiamide 0.03 kg, salt 0.61 kg, superphosphate lime 1.02 kg, 1.5 kg of fish cake was put in a bread granulator and mixed well, and granulated while supplying water appropriately. The obtained granulated material was placed in a shelf dryer at 105 ° C. for 4 hours, cooled to room temperature, and analyzed for dicyandiamide in the fertilizer by liquid chromatography.
As a result, the dicyandiamide content in the fertilizer was 0.027 kg, and the residual rate was 90%.
[0028]
Comparative Example-4
Manufacture of fertilizer of component 6-7-7 0.25 kg of lime nitrogen modification product, 0.29 kg of MAP, 3.02 kg of by-product nitrogen fertilizer, 0.03 kg of dicyandiamide, 0.61 kg of salt and 1.23 kg of superphosphate lime The mixture was put in a bread granulator and mixed well, and granulated while supplying water appropriately. The obtained granulated material was placed in a shelf dryer at 105 ° C. for 4 hours, cooled to room temperature, and analyzed for dicyandiamide in the fertilizer by liquid chromatography.
As a result, the dicyandiamide content in the fertilizer was 0.005 kg, and the residual rate was 16.7%.
[0029]
[Nitrification inhibitory effect test-1]
In the field conditions (soil: field soil in Iwaki city, nitrogen addition amount: 25 mg / 50 g soil moisture condition: 60% of maximum water capacity, temperature: 25 ° C.) using the fertilizer prepared in Example-2 and Comparative Example-3 Carried out. The results are shown below.
[0030]
[Table 1]
[0031]
From the results shown in Table 1, the fertilizer containing organic matter acts more positively on nitrification inhibition, and the effect of increasing the nitrification inhibition effect by the combined use of organic matter and dicyandiamide was shown.
[0032]
[Nitrification inhibitory effect test-2]
It was carried out under field conditions (soil: field soil in Yuki city, nitrogen addition amount: 20 mg / 50 g soil moisture condition: 60% of the maximum water capacity, temperature: 25 ° C.) using Example-2 and rapeseed oil cake. The results are shown below.
[0033]
[Table 2]
[0034]
From the results in Table 2, it was shown that rapid nitrification progresses with rapeseed oil cake alone, but it can be suppressed with combined use with the chemical fertilizer of the present invention.
[0035]
[Fertilization test]
Using a / 5000 Wagner pot, fertilizer prepared in Example-2 and normal high-grade chemical fertilizer (component 14-14-14) as 0.4g / pot with nitrogen component as a control, cultivate paddy rice (Koshihikari) did. Fertilization: 5/10 Transplantation: 5/13 Harvest: 10/1 (1999)
As a result, the yield per pot was 29.4 g for the control chemical fertilizer, whereas it was 33.9 g for the fertilizer of the present invention, which was 115% higher than the control chemical fertilizer. Obtained.
[0036]
【The invention's effect】
The chemical fertilizer of the present invention is a fertilizer with enhanced slow-acting effect, enhanced nitrification inhibition ability, and further organic matter enhancement, useful for labor saving of fertilization, improvement of yield and quality, and environmental conservation Therefore, it is expected to spread as a future fertilizer. Moreover, according to this invention, the manufacturing method of the chemical fertilizer which can prevent the modification | denaturation of dicyandiamide in the fertilizer manufacturing process can be provided. Furthermore, the fertilizer of the present invention is a fertilizer that can maintain the growing environment of crops in a preferable nutrient state and can increase yield and quality.
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JP5067520B2 (en) * | 2005-08-08 | 2012-11-07 | 独立行政法人国際農林水産業研究センター | Soil nitrification control method |
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CN105330426A (en) * | 2014-11-15 | 2016-02-17 | 深圳市芭田生态工程股份有限公司 | Organic carbon macro-element fertilizer containing nano synergist and preparation method of organic carbon macro-element fertilizer |
CN105367165A (en) * | 2014-11-15 | 2016-03-02 | 深圳市芭田生态工程股份有限公司 | Four-state nitrogen organic liquid fertilizer and its preparation method and use |
CN105367305A (en) * | 2015-12-24 | 2016-03-02 | 深圳市芭田生态工程股份有限公司 | Compound microbial fertilizer with disease and pest resistance as well as preparation method and application of compound microbial fertilizer |
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JPS5884196A (en) * | 1981-10-13 | 1983-05-20 | エス・カ−・ヴエ−・トロ−ストベルク・アクチエンゲゼルシヤフト | Nitrogen-containing fertilizer nitration inhibitor and manufacture |
JPH0640791A (en) * | 1991-07-31 | 1994-02-15 | Katakura Chitsukarin Kk | Paste-type fertilizer containing organic matter including dicyandiamide |
JPH11278973A (en) * | 1998-03-31 | 1999-10-12 | Chisso Corp | Preventive granular agent for nitration, compound fertilizer containing the same and method for cultivating crop |
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DE4405392C1 (en) * | 1994-02-21 | 1995-10-19 | Piesteritz Stickstoff | Active ingredient combinations for the inhibition or regulation of nitrification |
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Publication number | Priority date | Publication date | Assignee | Title |
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JPS5884196A (en) * | 1981-10-13 | 1983-05-20 | エス・カ−・ヴエ−・トロ−ストベルク・アクチエンゲゼルシヤフト | Nitrogen-containing fertilizer nitration inhibitor and manufacture |
JPH0640791A (en) * | 1991-07-31 | 1994-02-15 | Katakura Chitsukarin Kk | Paste-type fertilizer containing organic matter including dicyandiamide |
JPH11278973A (en) * | 1998-03-31 | 1999-10-12 | Chisso Corp | Preventive granular agent for nitration, compound fertilizer containing the same and method for cultivating crop |
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